DE2605935A1 - COMPOSITE FLAME POWDER - Google Patents

Description

FROM KREISLER SCHÖNWALD MEYER EISHOLD FUES FROM KREISLER KELLER SELTING

PATENT LAWYERS Dr.-Ing. by Kreisler + 1973

Dr.-Ing. K. Schönwald, Cologne Dr.-Ing. Th. Meyer, Cologne Dr.-Ing. K. W. Eishold, Bad Soden Dr. J. F. Fues, Cologne Dipl.-Chem. Alek von Kreisler, Cologne Dipl.-Chem. Carola Keller, Cologne Dipl.-Ing. G. Selting, Cologne

AvK / Ax

5 COLOGNE 1 13.2.76

DEICHMANNHAUS AT THE MAIN RAILWAY STATION

Metco, Inc., 11o1 Prospect Avenue, Westbury N.Y./USA

Composite flame spray powder

The invention relates to powdery flame spraying materials, which contain cheap cast iron as a larger component and still produce a hard, wear-resistant and abrasion-resistant coating that is easy to work with and has good properties as a bearing material has the ability to form.

In the field of flame spraying it is well known the most varied types of metal powders, mixtures and composites depending on the type and the Properties of the flame-sprayed coating to be produced splash on. For the production of hard, wear-resistant and abrasion-resistant coatings that are up to good Surface finish sanded and in machines can be used as wear-resistant bearing surfaces, it has generally been necessary to use relatively expensive Metals such as molybdenum, self-contained or self-amalgamating alloys based on nickel and the like. to use.

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Telephone: (0221) 23 4541-4 Telex: 8332307 dopa d Telegram: Dompatent Cologne

Try to reduce the cost of these flame spray materials for example by mixing the relatively expensive molybdenum with relatively cheap cast iron, did not have satisfactory results, and so did the coatings produced by spraying these mixtures did not show all of the desirable properties.

The subject of the invention is a flame spraying material, which contains relatively cheap cast iron as a larger component and still has a hard, Able to form a wear-resistant and abrasion-resistant coating that can be ground to a smooth surface and provides an excellent storage area for use between moving machine parts.

According to the invention it has been found that a hard, wear-resistant and abrasion-resistant coating, which under formation A smooth, good surface can be sanded and is excellent as a storage area between them moving machine parts, using a flame spraying material, the cheap cast iron than larger Contains constituent, can be produced if the flame spraying material is made in the form of a composite powder individual particles are present which contain molybdenum and boron in addition to cast iron.

The term "cast iron" as used herein refers to an alloy of iron and carbon that are commonly used Contains varying amounts of silicon, manganese, phosphorus and sulfur, with the carbon in excess is present over the amount that can be kept in solid solution in austenite at the autectic temperature. Alloy cast iron improves the mechanical properties, e.g. corrosion, heat and wear resistance, and the addition of alloying elements has a considerable influence on the graphitization. as other common alloy additives in cast iron

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Molybdenum, chromium, nickel, vanadium and copper are possible.

A composite flame spray powder is understood to mean in the flame spraying technique a powder, the individual particles of which contain several components that individually or are present separately, i.e. are not alloyed with one another, but as a structural unit that forms the powder particles, are connected to each other.

The particles of the composite flame spraying material according to Invention must therefore contain the cast iron, a molybdenum component and a boron component that are not mutually exclusive alloyed, but structurally united in each individual particle.

The individual components can be used in any known or desired manner to form the composite particles can be combined, for example in the form of aggregates or the like. However, the composite material according to the invention preferably in the form of a clad powder, the individual particles of which consist of a cast iron core with a coating that contains the molybdenum component and the boron component, in particular the form of individual small particles of the molybdenum and boron components that are bonded to the Surface of the cast iron core are bound.

The molybdenum component can consist of molybdenum itself and / or a ferromolybdenum alloy, the at least Contains 50% Mo, preferably 55 to 75% Mo.

The boron component can consist of Eor itself and / or a ferroboron alloy, which, based on the alloy, Contains 10 to 30% boron, preferably 18% boron.

The particles of the composite flame spray powder according to FIG Invention should be at least 50 wt .-% cast iron, about

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1o to 50% by weight, preferably 15 to 3o% by weight, in particular about 20% by weight of molybdenum, about 0.1 to 3% by weight, preferably 1% by weight of boron, based in each case on the total weight of cast iron and molybdenum.

The individual particles should have a size and grain structure, as are customary in flame spraying technology, e.g. a size between about 3 u and 0.25 mm (6o mesh

ihen 1 ο u and 1o5

US Standard), preferably between 1o u and 1o5 μ (14o mesh US Standard).

According to a particularly preferred method, the composite flame spray powder manufactured by powdery white cast iron, which has a particle size between about 88 (17o mesh U.S. Standard) and 15 ii has, with 2o wt .-% Molybdenum and 1% by weight boron (based on the total weight of cast iron and molybdenum), both of which have a particle size of 44 µ (325 mesh), preferably between about 0.1 and 2o µ, is clad or clad.

The cast iron can be coated, clad or coated with the finer molybdenum and boron particles in any known or customary manner, e.g. by mixing the molybdenum and boron in a binder, e.g. a resin varnish ^: or varnish, mixing the mixture with the cast iron and drying or curing the binder.

Usual phenolic resin lacquers are particularly preferred as binders. Examples of other suitable binders include customary epoxy or alkyd resin lacquers, lacquer containing drying oils, for example tung oil and linseed oil, and rubber and latex binders. The binder may include a resin in which to form a dried or ER \ staring film is not the evaporation of a solvent is required i. The binder can thus contain a catalyzed resin. j

The expression "enveloping" or "plating" ("coating" or "cladding") is used here in the flame spraying technique common sense 609 3 35/0342

second hand. It does not require a uniform or closed coating and only indicates the shape in the finer particles are bound, so to speak, to the surface of the cast iron.

The powders are sprayed in the usual way with a powder flame spray gun sprayed, but it is also possible to use the powder with a binder, e.g. a plastic or rubber, combine into a wire or rod and use a flame spray gun for this Spray wire to spray. Preferably, a flame spray system should be used that provides enough heat able to produce that at least the molybdenum component of the composite material is softened by heat. It proved Appropriate to the material with a plasma flame spray gun to splash.

The flame-sprayed layers formed are extremely hard and wear-resistant, and show excellent abrasion resistance and have excellent machinability and grindability. You can get wet with a grinding wheel that comes with Silicon carbide of grain size 60 is provided as an abrasive, to a smooth surface with a roughness grind from e.g. 127/1 000 000 to .508 / 1 000 000 mm (arithmetic mean) (5 - 2o micro inches), determined with a standard surface testing device "Profilometer Model QC "(made by Micrometrical Manufacturing Co., Ann Arbor, Mich. USA) with a cut length (cutoff) of o, 762 mm (o, o3o ").

The coatings are ideal as storage and work surfaces on machine parts, e.g. for coating the circumference of piston rings, cylinder walls, piston skirts, trochoid of rotary engines, seals and End plates, crankshafts, roller bearings, bearing sleeves, impeller shafts, gearbox bearings, impellers of fuel pumps, Screw conveyors, wire or rope winches, Biremstrorr.meln, Release forks, doctor blades, thread guides, agricultural

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economic devices and tools, motor shafts, lathe rail guides, Lathe and grinding machine tips, cam followers and rams and cylinder liners.

When the molybdenum component is bonded to the cast iron, preferably as a cladding or coating combined, it causes a substantial reduction in decarburization during spraying. The boron works as an interstitial hardener and as a means to increase the density and quality of the coating. Overall, the Components in interaction with each other in the respective flame spray form an excellent, hard Cover with high abrasion and wear resistance.

The invention is further illustrated by the following examples.

Example 1

1785 g of cast iron powder with a particle size between 15 and 88 li (17o mesh US standard) are mixed in a vessel at room temperature with about 227 g of a conventional phenolic resin varnish with a solids content of about 10% for 5 minutes. Then 454 g of molybdenum powder and 22.7 g of boron powder, each with a particle size of 0.1 to 20 μm, are slowly added and mixed in thoroughly. The wet slurry is then heated with stirring until a dry mixture is obtained. The mixture is then placed well dried in an oven at a temperature of about 79 ⁰ C and to remove large agglomerates through a sieve having a mesh of 88 u (17o mesh). In this way a composite flame spray powder is obtained, the particles of which consist of a cast iron core which is coated with finer molybdenum and boron particles.

This flame spray powder is then used with a plasma flame, spray gun sold under the designation "Type 3MB" in the

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Commercially available (manufactured by the applicant) using a GE nozzle and a # 2 powder nozzle Argon as the primary gas under a pressure of 7 atm and a flow rate of 2.266 Nm / h. (8o standard cubic feet per hour) and using hydrogen as seconds

2 därgas under a pressure of 3.5 kg / cm and a flow rate of o.566 Nm / h (2o standard cubic feet per hour). The plasma gun is at average 500 A and 65 V using 0.425 Nm carrier gas / hour. (15 standard cubic feet per hour). That Powder is with a throughput of 4.536 kg / hour. sprayed by the gun onto mild steel as a workpiece that passed through Shot blasting using air under a pressure of 6.3 kg / cm. For cooling purposes, additional air jets are directed onto the workpiece, but not in such a way that the spray jet is affected.

The spray layer formed has a thickness of 0.762 to 1.27 mm (0.03 to 0.05 inches) and becomes to a roughness from 254/1 ooo ooo to 5o8 / 1 ooo ooo mm (1o to 2o micro inches) (arithmetic mean), measured with a Standard surface testing device "Profilometer Model QC" using a section length of 0.762 mm, sanded.

The final sprayed layer will be 51 µm thick 1.02 mm (o, oo2 to o, o4o inches) and a hardness of about 5o, measured on the Rockwell C scale. She has excellent Wear and abrasion resistance. The powder can be used to coat piston rings or used for other purposes mentioned above; will. '

Example 2 j

A spray layer, which with a similar powder v / ie! in example 1, but with 30% molybdenum and 0.5% boron, the same is produced according to example 1 very similar to the spray layer, but has only 90% '

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the wear resistance of those produced according to Example 1 Spray layer.

An analog spray coating that has been formed from a flame spray powder consisting only of white cast iron has a Rockwell hardness of 43 on the C scale and only shows about 70% of the wear resistance of the Spray layer produced according to Example 1 and poor abrasion resistance. :

A spray layer that, by spraying a mixture: made of white cast iron and molybdenum with a molybdenum content of 30% has been applied in the same way, shows only a Rockwell C hardness of 40, only 60% of the wear resistance of that applied according to Example 1 Spray layer and a lower abrasion resistance.

A mixture of 75% molybdenum and 25% of a self-going or self-amalgamating alloy resulted in spraying in the same way a sprayed layer with a Rockwell C hardness of 44 and a wear resistance, of 50% of the spray coating produced according to Example 1.

When molybdenum wire was sprayed under the same conditions: a sprayed layer was formed that had a Rockwell C hardness of 4Ό and 50% of the wear resistance of the spray layer produced according to Example 1 and only Ground to a roughness of 635 to 1016/1000000 mm (25 - 40 micro inches) (arithmetic mean) could be.

Example 3

A flame spray powder was based on that described in Example 1 V / e, but made without the use of boron. The powder was prepared in the same way as in Example 1 sprayed. The spray layer produced had a Rockwell C hardness of 42, only about 60% of the wear resistance that prepared according to Example 1

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-9 spray coat and pretty good abrasion resistance.

Example 4

A mixture is formed from 80% by weight powdered white cast iron having a particle size between about 44 and 88 µm (325 mesh and 17o mesh), 15% by weight carbon aromeric ferromolybdenum alloy containing 62% by weight molybdenum and having a particle size of 15 µm and smaller, and 5% by weight of ferrous boron alloy containing 18% by weight of boron and having a particle size of 15µ and smaller. A slurry is prepared from these ingredients in 6% by weight of a phenolic resin varnish containing about 10% solids, with thorough mixing. Mixing is continued until a dry mixture has been obtained consisting of the cast iron, the particles of which are coated with the finer particles of the ferro-molybdenum alloy and ferro-boron alloy. The powder is flame sprayed in the manner described in Example 1. A spray layer is formed which has a thickness of 1.524 mm (0.060 mesh) and is ground to a roughness of about 2o3.2 to 508 / 1,000,000 mm (8 to 20 micron inches) (arithmetic mean). The final coating has a '■ thickness of 1.27 mm (o, o5o inches), a Rockwell-C hardness of 55 and excellent Verschließfestigkeit and abrasion resistance, the wear resistance at 4o% higher produced than that for the of Example 1 Spray layer specified wear resistance

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Claims (6)

Claims 1) thermal spray powder in the form of a composite material, 'characterized in that its individual particles as a non-alloyed with one another components, a cast iron components, a molybdenum component and _a: contain boron component, as a molybdenum component of molybdenum and / or a ferro-molybdenum alloy and a boron component boron and / or boron alloy available the powder contains about 10 to 50 weight percent molybdenum and about 0.1 to 3 weight percent boron based on the total weight of cast iron and molybdenum, and the cast iron component is present in an amount of at least 50 weight percent is. 2) flame spray powder according to claim 1, characterized in that the particles have a cast iron core and a shell containing the molybdenum and boron components. 3) flame spray powder according to claim 1 and 2, characterized in that the cast iron core has a particle size between about 15 and 88 u and is coated with a binder containing fine particles of the molybdenum and boron components. 4) flame spray powder according to claim 1 to 3, characterized in that that the individual particles have a core of white cast iron with a size between 15 and (17o mesh) 88 u ^ have and with a binder to the surface of the cast iron core, 0.1 to 20 μ particles of the molybdenum and boron components, the molybdenum in an amount of about 20 wt .-% and the boron in an amount of about 1% by weight, based in each case on the total weight of cast iron and molybdenum, is present. 609835/0342 5) flame spray powder according to claim 1 to 4, characterized in that it is a molybdenum component Contains ferro-molybdenum alloy, which contains 55 to 75% by weight Contains molybdenum. 6) flame spray powder according to claim 1 to 5, characterized in that it is a boron component Contains ferroboron alloy, which contains about 10 to 30 wt .-% boron. 609835/0342